A semiconductor structure and a forming method thereof are provided. One form of a semiconductor structure includes: a first device structure, including a first substrate and a first device formed on the first substrate, the first device including a first channel layer structure located on the first substrate, a first device gate structure extending across the first channel layer structure, and a first source-drain doping region located in the first channel layer structure on two sides of the first device gate structure; and a second device structure, located on a front surface of the first device structure, including a second substrate located on the first device structure and a second device formed on the second substrate, the second device including a second channel layer structure located on the second substrate, a second device gate structure extending across the second channel layer structure, and a second source-drain doping region located in the second channel layer structure on two sides of the second device gate structure, where projections of the second channel layer structure and the first channel layer structure onto the first substrate intersect non-orthogonally. The electricity of the first device can be led out according to the present disclosure.

A semiconductor device includes: a first semiconductor chip including a first MOSFET of n-type and a first parasitic diode; and a second semiconductor chip including a second MOSFET of n-type and a second parasitic diode. A first source electrode and a first gate wiring are formed in a first front surface of the first semiconductor chip, and a first drain electrode is formed in a first back surface of the first semiconductor chip. A second source electrode and a second gate wiring are formed in a second front surface of the second semiconductor chip, and a second drain electrode is formed in a second back surface of the second semiconductor chip. The first front surface and the second front surface face each other such that the first source electrode and the second source electrode are in contact with each other via a conductive paste.

An electronic module has a first substrate 11, a first electronic element 13 provided on one side of the first substrate 11, a first connection body 60 provided on one side of the first electronic element 13, a second electronic element 23 provided on one side of the first connection body 60, a second substrate 21 provided on one side of the second electronic element 23, and an abutment body 250 that abuts on a face on one side of the second electronic element 23 and is capable of imparting a force toward one side with respect to the second substrate 21.

A semiconductor device is provided and includes a first substrate including a first transistor; a laser reflection layer on the first transistor; and a second substrate on the laser reflection layer, the second substrate including a second transistor.

A semiconductor device, includes: gate electrodes spaced apart from each other and on a substrate; channel structures penetrating the gate electrodes, each of channel structures including a channel layer, a gate dielectric layer between the channel layer and the gate electrodes, a channel insulating layer filling between the channel layers, a channel pad on the channel insulating layer; and separation regions penetrating the gate electrodes, and spaced apart from each other, wherein the gate dielectric layer extends upwardly, further than the channel layer upwardly such that a portion of an inner side surface of the gate dielectric layer contacts the channel pad, the channel pad includes a lower pad on an upper end of the channel layer and the inner side surface of the gate dielectric layer, and having a first recess between the inner side surfaces of the gate dielectric layer; and an upper pad having a first portion in the first recess and a second portion extending from the first portion in a direction, parallel to an upper surface of the substrate on the first portion.

A diode pack housing for a rotating rectifier assembly can include a body having an interior surface defining an interior cavity open on a first end and configured to contain a diode pack and a plurality of bus bar channels defined axially on or in the inner surface in the interior cavity. The plurality of bus bar channels can be five or less bus bar channels.

An embodiment related to a device. The device includes a first die with first and second die surfaces. The second die surface is bonded to a first die attach pad (DAP) disposed on a first substrate surface of a package substrate and the first die surface includes a first die contact pad. The device also includes a first clip bond including a first clip bond horizontal planar portion attached to the first die contact pad on the first die surface, and a first clip bond vertical portion disposed on an edge of the first clip bond horizontal planar portion. The first clip bond vertical portion is attached to a first substrate bond pad on the first substrate surface. The device further includes a first conductive clip-die bonding layer with spacers on the first die contact pad of the first die. The first conductive clip-die bonding layer bonds the first clip bond horizontal planar portion to the first die contact pad, and the spacers maintain a uniform Bond Line Thickness (BLT) of the first conductive clip-die bonding layer.

An electronic module has a first electronic unit having a first substrate 11, a first conductor layer 12 provided on one side of the first substrate 11, and a first electronic element 13 provided on one side of the first conductor layer 12, a first connection body 60 provided on one side of the first electronic element 13, and a second electronic unit having a second electronic element 23 provided on one side of the first connection body 60. The first connection body 60 has a first head part 61 and a plurality of support parts 65 extending from the first head part 61. The electronic module is characterized by that the support part 65 abuts on the first substrate 11 or the first conductor layer 12.

Multichip package manufacturing process is disclosed to form external pins at one side or each side of die-bonding area of package carrier board and to bond first IC and second IC to die-bonding area in stack. First IC and second IC each comprise transistor layer with core circuits, plurality of metal layers, plurality of VIA layers and solder pad layer. During production of first IC, design of at least one metal layer, VIA layer and dummy pads can be modified according to change of design of second IC. After chip probing, die sawing and bonding, wire bonding, packaging and final test are performed to package the package carrier board, first IC and second IC into automotive multichip package, achieving purpose of first IC only need to modify at least one layer or more than one layer to cooperate with second IC design change to carry out multichip packaging process.

There is provided a semiconductor device including: a first semiconductor element including a first gate electrode, a first source electrode, and a first drain electrode; a second semiconductor element including a second gate electrode, a second source electrode, and a second drain electrode; a gate lead, a source lead, a first drain lead, and a second drain lead; and a resin part, wherein the first gate electrode and the first source electrode, and the first drain electrode are provided on opposite sides to each other in a first direction, wherein the second gate electrode and the second source electrode, and the second drain electrode are provided on opposite sides to each other in the first direction, wherein the first gate electrode and the second gate electrode are opposed to the first source electrode and the second source electrode, respectively, in the first direction.